Saved in:
Bibliographic Details
Main Authors: Zhang, Junyin, Zheng, Shuhang, Cai, Jiachen, Denney, Connor, Li, Zihan, Zhang, Yichi, Ou, Xin, Santamaria-Botello, Gabriel, Kippenberg, Tobias J.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.06176
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911556947673088
author Zhang, Junyin
Zheng, Shuhang
Cai, Jiachen
Denney, Connor
Li, Zihan
Zhang, Yichi
Ou, Xin
Santamaria-Botello, Gabriel
Kippenberg, Tobias J.
author_facet Zhang, Junyin
Zheng, Shuhang
Cai, Jiachen
Denney, Connor
Li, Zihan
Zhang, Yichi
Ou, Xin
Santamaria-Botello, Gabriel
Kippenberg, Tobias J.
contents Decades of progress in radiofrequency (RF) transistors and receiver frontends have profoundly impacted wireless communications, remote sensing, navigation, and instrumentation. Growing demands for data throughput in 6G networks, timing precision in positioning systems, and resolution in atmospheric sensing and automotive radar have pushed receiver frontends into the millimeter-wave (mmW) and sub-mmW/THz regimes. At these frequencies, however, the noise performance of field-effect transistors (FETs) degrades rapidly due to parasitic effects, limited carrier mobility, hot electrons, and shot noise. Parametric transducers that couple electromagnetic signals to optical fields offer quantum-limited sensitivity at room temperature. Electro-optic materials enable receivers that convert RF signals into optical phase shifts. While early demonstrations used resonant devices and recent efforts have focused on cryogenic microwave-to-optical quantum transduction, room-temperature electro-optic receivers have yet to achieve noise figures comparable to their electronic counterparts. Here we demonstrate a room-temperature integrated cavity electro-optic mmW receiver on a lithium tantalate (LiTaO3) photonic integrated circuit with 2.5% on-chip photon-number transduction efficiency, achieving 250 K noise temperature at 59.33 GHz--matching state-of-the-art LNAs. We report the first direct resolution of thermal noise in cavity electro-optic transduction, showing the system is fundamentally limited by thermal photon occupation (~100) in the mmW cavity. Our work establishes integrated photonics as a path to surpass electronic LNAs while offering exceptional resilience to strong electromagnetic inputs and immunity to EMI, establishing cavity electro-optics as a low-noise, chip-scale, EMI-resilient receiver frontend for mmW applications and scalable analog processing in the optical domain.
format Preprint
id arxiv_https___arxiv_org_abs_2510_06176
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle An integrated photonic millimeter-wave receiver with sub-ambient noise
Zhang, Junyin
Zheng, Shuhang
Cai, Jiachen
Denney, Connor
Li, Zihan
Zhang, Yichi
Ou, Xin
Santamaria-Botello, Gabriel
Kippenberg, Tobias J.
Optics
Quantum Physics
Decades of progress in radiofrequency (RF) transistors and receiver frontends have profoundly impacted wireless communications, remote sensing, navigation, and instrumentation. Growing demands for data throughput in 6G networks, timing precision in positioning systems, and resolution in atmospheric sensing and automotive radar have pushed receiver frontends into the millimeter-wave (mmW) and sub-mmW/THz regimes. At these frequencies, however, the noise performance of field-effect transistors (FETs) degrades rapidly due to parasitic effects, limited carrier mobility, hot electrons, and shot noise. Parametric transducers that couple electromagnetic signals to optical fields offer quantum-limited sensitivity at room temperature. Electro-optic materials enable receivers that convert RF signals into optical phase shifts. While early demonstrations used resonant devices and recent efforts have focused on cryogenic microwave-to-optical quantum transduction, room-temperature electro-optic receivers have yet to achieve noise figures comparable to their electronic counterparts. Here we demonstrate a room-temperature integrated cavity electro-optic mmW receiver on a lithium tantalate (LiTaO3) photonic integrated circuit with 2.5% on-chip photon-number transduction efficiency, achieving 250 K noise temperature at 59.33 GHz--matching state-of-the-art LNAs. We report the first direct resolution of thermal noise in cavity electro-optic transduction, showing the system is fundamentally limited by thermal photon occupation (~100) in the mmW cavity. Our work establishes integrated photonics as a path to surpass electronic LNAs while offering exceptional resilience to strong electromagnetic inputs and immunity to EMI, establishing cavity electro-optics as a low-noise, chip-scale, EMI-resilient receiver frontend for mmW applications and scalable analog processing in the optical domain.
title An integrated photonic millimeter-wave receiver with sub-ambient noise
topic Optics
Quantum Physics
url https://arxiv.org/abs/2510.06176